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Transcript
Potential Energy
~March 1, 2006
Coming Up

Exam on Friday
 Material
through today.
 Look for current WA

Next Week
 Important
Topic: Conservation of Momentum
and collisions between objects.
Potential Energy

Potential energy is the energy associated with
the configuration of a system of objects that
exert forces on each other
 This
can be used only with conservative forces
 Conservative forces are NOT Republicans
 When conservative forces act within an isolated
system, the kinetic energy gained (or lost) by the
system as its members change their relative
positions is balanced by an equal loss (or gain) in
potential energy.

This is Conservation of Mechanical Energy
Types of Potential Energy

There are many forms of potential energy, including:





One form of energy in a system can be converted into
another



Gravitational
Electromagnetic
Chemical
Nuclear
Nuclear heat easy
Heat Nuclear probably impossible!
Conversion from one type to another type of energy is
not always reversible.
Systems with Multiple Particles
We can extend our definition of a system
to include multiple objects
 The force can be internal to the system
 The kinetic energy of the system is the
algebraic sum of the kinetic energies of
the individual objects

 Sometimes,
the kinetic energy of one of the
objects may be negligible
System Example








This system consists of Earth and
a book
Do work on the system by lifting
the book through Dy
The work done by you is mg(yb –
y a)
At the top it is at rest.
The amount of work that you did
is called the potential energy of
the system with respect to the
ground.
The PE’s initial value is mgya
The FINAL value is mgyb
The difference is the work done.
Let’s drop the book from yb and see
what it is doing at ya.
v  v  2 g ( yb  ya )
2
v
2
0
v02  0
Multiply by m and divide by 2:
1 2
mv f  mg ( yb  ya )
2
The decrease in Potential Energy equals the increase in Kinetic Energy
Potential Energy
The energy storage mechanism is called
potential energy
 A potential energy can only be associated
with specific types of forces (conservative)
 Potential energy is always associated with
a system of two or more interacting
objects

Gravitational Potential Energy
Gravitational Potential Energy is
associated with an object at a given
distance above Earth’s surface
 Assume the object is in equilibrium and
moving at constant velocity
 The work done on the object is done by
Fapp and the upward displacement is

Dr  Dyˆj
Gravitational Potential Energy,
cont
W   Fapp   Dr

W  (mgˆj)   yb  ya  ˆj
W  mgyb  mgya

The quantity mgy is identified as the
gravitational potential energy, Ug
 Ug

= mgy
Units are joules (J)
Energy Problems
Draw a diagram of the situation.
 ESTABLISH AN ORIGIN.
 THE POTENTIAL ENERGY OF A
PARTICAL OF MASS M IS ALWAYS
MEASURED WITH RESPECT TO THIS
ORIGIN.
 The potential energy of a particle is
defined as being ZERO when it is at the
origin.
 At some height above the origin, the value
of the PE is mgh.

Gravitational Potential Energy,
final


The gravitational potential energy depends
only on the vertical height of the object above
Earth’s surface
In solving problems, you must choose a
reference configuration for which the
gravitational potential energy is set equal to
some reference value, normally zero
 The
choice is arbitrary because you normally
need the difference in potential energy, which
is independent of the choice of reference
configuration
Conservation of Mechanical
Energy

The mechanical energy of a system is the
algebraic sum of the kinetic and potential
energies in the system
 Emech

= K + Ug
The statement of Conservation of Mechanical
Energy for an isolated system is Kf + Uf = Ki+
Ui
 An
isolated system is one for which there are no
energy transfers across the boundary
Let’s look at the more general case.
y=h
m
W=0
d
D
F
y=0
(origin)
W=mgD
We do work to
move mass to
y=h. W=mgh
m
m
ANY PATH


Can be broken up into a series of very small
vertical moves and horizontal moves.
The horizontal moves require no work.
 The
force is at right angles to the motion. Dot
product is zero.

The vertical moves are
W   FD  F  D  Fh  mgh
Conservation of Mechanical
Energy, example




Look at the work done
by the book as it falls
from some height to a
lower height
Won book = DKbook
Also, W = mgyb – mgya
So, DK = -DUg
Elastic Potential Energy



Elastic Potential Energy is associated with a
spring
The force the spring exerts (on a block, for
example) is Fs = - kx
The work done by an external applied force on a
spring-block system is
= ½ kxf2 – ½ kxi2
 The work is equal to the difference between the initial
and final values of an expression related to the
configuration of the system
W
Elastic Potential Energy, cont



This expression is the
elastic potential energy:
Us = ½ kx2
The elastic potential
energy can be thought of
as the energy stored in
the deformed spring
The stored potential
energy can be converted
into kinetic energy
Elastic Potential Energy, final

The elastic potential energy stored in a spring is
zero whenever the spring is not deformed (U = 0
when x = 0)
 The
energy is stored in the spring only when the
spring is stretched or compressed


The elastic potential energy is a maximum when
the spring has reached its maximum extension
or compression
The elastic potential energy is always positive
 x2
will always be positive
Problem Solving Strategy –
Conservation of Mechanical Energy

Define the isolated system and the
initial and final configuration of the
system
 The
system may include two or more
interacting particles
 The system may also include springs or
other structures in which elastic potential
energy can be stored
 Also include all components of the system
that exert forces on each other
Problem-Solving Strategy, 2

Identify the configuration for zero potential
energy
 Include
both gravitational and elastic potential
energies
 If more than one force is acting within the
system, write an expression for the potential
energy associated with each force
Problem-Solving Strategy, 3
If friction or air resistance is present,
mechanical energy of the system is not
conserved
 Use energy with non-conservative forces
instead

Problem-Solving Strategy, 4

If the mechanical energy of the system is
conserved, write the total energy as
 Ei
= Ki + Ui for the initial configuration
 Ef = Kf + Uf for the final configuration

Since mechanical energy is conserved, Ei
= Ef and you can solve for the unknown
quantity
Conservation of Energy,
Example 1 (Drop a Ball)

Initial conditions:




Ei = Ki + Ui = mgh
The ball is dropped, so Ki = 0
The configuration for zero
potential energy is the
ground
Conservation rules applied
at some point y above the
ground gives

½ mvf2 + mgy = mgh
Conservation of Energy,
Example 2 (Pendulum)




As the pendulum swings, there
is a continuous change
between potential and kinetic
energies
At A, the energy is potential
At B, all of the potential energy
at A is transformed into kinetic
energy
 Let zero potential energy
be at B
At C, the kinetic energy has
been transformed back into
potential energy
Conservation of Energy,
Example 3 (Spring Gun)


Choose point A as the
initial point and C as
the final point
EA = EC
 KA
+ UgA + UsA = KA +
UgA + UsA
 ½ kx2 = mgh
Conservative Forces
The work done by a conservative force on
a particle moving between any two points
is independent of the path taken by the
particle
 The work done by a conservative force on
a particle moving through any closed path
is zero

 A closed
path is one in which the beginning
and ending points are the same
Conservative Forces, cont

Examples of conservative forces:
 Gravity
 Spring

force
We can associate a potential energy for a
system with any conservative force acting
between members of the system
 This
can be done only for conservative forces
 In general: WC = - DU
Nonconservative Forces
A nonconservative force does not satisfy
the conditions of conservative forces
 Nonconservative forces acting in a system
cause a change in the mechanical energy
of the system

Mechanical Energy and
Nonconservative Forces

In general, if friction is acting in a system:
 DEmech
= DK + DU = -ƒkd
 DU is the change in all forms of potential
energy
 If friction is zero, this equation becomes the
same as Conservation of Mechanical Energy
Nonconservative Forces, cont


The work done
against friction is
greater along the red
path than along the
blue path
Because the work
done depends on the
path, friction is a
nonconservative force
Problem Solving Strategies –
Nonconservative Forces


Define the isolated system and the initial and
final configuration of the system
Identify the configuration for zero potential
energy
 These

are the same as for Conservation of Energy
The difference between the final and initial
energies is the change in mechanical energy
due to friction
Nonconservative Forces,
Example 1 (Slide)
DEmech = DK + DU
DEmech =(Kf – Ki) +
(Uf – Ui)
DEmech = (Kf + Uf) –
(Ki + Ui)
DEmech = ½ mvf2 – mgh
= -ƒkd
Nonconservative Forces,
Example 2 (Spring-Mass)


Without friction, the
energy continues to be
transformed between
kinetic and elastic
potential energies and
the total energy remains
the same
If friction is present, the
energy decreases

DEmech = -ƒkd
Nonconservative Forces,
Example 3 (Connected Blocks)



The system consists of
the two blocks, the
spring, and Earth
Gravitational and
potential energies are
involved
The kinetic energy is
zero if our initial and
final configurations are
at rest
Connected Blocks, cont
Block 2 undergoes a change in
gravitational potential energy
 The spring undergoes a change in elastic
potential energy
 The coefficient of kinetic energy can be
measured

Conservative Forces and
Potential Energy
Define a potential energy function, U, such
that the work done by a conservative force
equals the decrease in the potential
energy of the system
 The work done by such a force, F, is
W   F dx  DU

xf
C
 DU
xi
x
is negative when F and x are in the same
direction
Conservative Forces and
Potential Energy


The conservative force is related to the potential
energy function through
dU
Fx  
dx
The x component of a conservative force acting
on an object within a system equals the negative
of the potential energy of the system with
respect to x
Conservative Forces and
Potential Energy – Check

Look at the case of a deformed spring
dU s
d 1 2
Fs  
   kx   kx
dx
dx  2

 This
is Hooke’s Law
Energy Diagrams and
Equilibrium



Motion in a system can be observed in terms of a graph
of its position and energy
In a spring-mass system example, the block oscillates
between the turning points, x = ±xmax
The block will always accelerate back toward x = 0
Energy Diagrams and Stable
Equilibrium



The x = 0 position is one
of stable equilibrium
Configurations of stable
equilibrium correspond to
those for which U(x) is a
minimum
x=xmax and x=-xmax are
called the turning points
Energy Diagrams and Unstable
Equilibrium




Fx = 0 at x = 0, so the
particle is in equilibrium
For any other value of x,
the particle moves away
from the equilibrium
position
This is an example of
unstable equilibrium
Configurations of
unstable equilibrium
correspond to those for
which U(x) is a maximum
Neutral Equilibrium
Neutral equilibrium occurs in a
configuration when U is constant over
some region
 A small displacement from a position in
this region will produce either restoring or
disrupting forces

Potential Energy in Molecules

There is potential energy associated with
the force between two neutral atoms in a
molecule which can be modeled by the
Lennard-Jones function
  12   6 
U ( x )  4       
 x  
 x 
Potential Energy Curve of a
Molecule


Find the minimum of the function (take the derivative and
set it equal to 0) to find the separation for stable
equilibrium
The graph of the Lennard-Jones function shows the
most likely separation between the atoms in the
molecule (at minimum energy)
Force Acting in a Molecule




The force is repulsive (positive) at small separations
The force is zero at the point of stable equilibrium
The force is attractive (negative) when the separation
increases
At great distances, the force approaches zero